What is Deterministic Lateral Displacement (DLD)?
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microfluidic design
Organ-on-Chip Design: Materials, Challenges, and a New Approach to Accelerate Innovation
How to Master Organ-on-Chip Design: Tools, Methods & Materials Introduction to Organ-On-Chip Organ-on-Chip (OoC) systems are transforming biomedical research by enabling more physiologically relevant models than traditional 2D cell cultures and animal testing. These microengineered systems integrate microfluidics, tissue engineering, and cell biology to simulate human organ functions in vitro. As the field advances, robust
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Microfluidic Mixing: A Design Guideline for Efficient Lab-on-a-Chip Devices
Microfluidic Mixing: How to Design Efficient Micromixers for Lab-on-a-Chip Devices Microfluidic mixing is at the core of high-performance lab-on-a-chip systems. From PCR preparation to chemical synthesis and diagnostics, precise and fast mixing at the microscale is essential. But in microfluidics, where laminar flow dominates, achieving effective mixing is notoriously difficult. This guide provides design principles,
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Microfluidic Cell Culture: Alternative to PDMS and microfluidic design
Microfluidic Cell Culture: Alternative to PDMS and Microfluidic Design Introduction Microfluidic cell culture has emerged as a powerful tool in the biomedical and pharmaceutical fields. By integrating cell culture into microfluidic devices, researchers can better mimic physiological conditions, control environmental factors, and conduct high-throughput screenings in a much more efficient and reproducible manner. This blog
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Microfluidics Design with FLUI’DEVICE
A Comprehensive Microfluidics Module Library Microfluidics is revolutionizing industries from biomedical research to diagnostics, yet designing microfluidic devices can often be complex and time-consuming. FLUI’DEVICE is here to change that. Our intuitive platform makes microfluidics design faster and easier than ever, empowering researchers and engineers with powerful tools that streamline the process. FLUI’DEVICE also includes
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Droplet-Based Microfluidics: A Design Guideline
Droplet-Based Microfluidics: A Design Guideline Introduction Introduction Droplet-based microfluidics has emerged as a powerful tool for applications in biotechnology, chemistry, and material sciences. By leveraging the ability to generate and manipulate discrete droplets in immiscible phases, this technique offers high throughput, precise control over reaction conditions, and minimal sample consumption. It’s important to highlight that
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Microfluidic design – Step by step
Introduction to Microfluidics and Microfluidic Design Microfluidics represents a cutting-edge domain focused on the control of fluids at a microscopic level. It finds extensive application in areas such as medical diagnostics, chemical analysis, and drug discovery research. Microfluidic design can be challenging for researchers, PhDs, or engineers. A standard microfluidic device has channels and chambers.
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